Litcius/Paper detail

Stability of Ligand-induced Protein Conformation Influences Affinity in Maltose-binding Protein

Marco van den Noort, Marijn de Boer, Bert Poolman

2021Journal of Molecular Biology29 citationsDOIOpen Access PDF

Abstract

Our understanding of what determines ligand affinity of proteins is poor, even with high-resolution structures available. Both the non-covalent ligand-protein interactions and the relative free energies of available conformations contribute to the affinity of a protein for a ligand. Distant, non-binding site residues can influence the ligand affinity by altering the free energy difference between a ligand-free and ligand-bound conformation. Our hypothesis is that when different ligands induce distinct ligand-bound conformations, it should be possible to tweak their affinities by changing the free energies of the available conformations. We tested this idea for the maltose-binding protein (MBP) from Escherichia coli. We used single-molecule Förster resonance energy transfer (smFRET) to distinguish several unique ligand-bound conformations of MBP. We engineered mutations, distant from the binding site, to affect the stabilities of different ligand-bound conformations. We show that ligand affinity can indeed be altered in a conformation-dependent manner. Our studies provide a framework for the tuning of ligand affinity, apart from modifying binding site residues.

Topics & Concepts

Ligand (biochemistry)Maltose-binding proteinChemistryFörster resonance energy transferLigand efficiencyAffinitiesPlasma protein bindingProtein structureBinding siteCrystallographyStereochemistryBiophysicsBiochemistryBiologyReceptorFluorescenceFusion proteinGenePhysicsQuantum mechanicsRecombinant DNAProtein Structure and DynamicsBacterial Genetics and BiotechnologyRNA and protein synthesis mechanisms